Abstract: A polishing article for chemical mechanical polishing. The polishing article includes a generally elongated polishing sheet with a polishing surface. The polishing article is formed from a material that is substantially opaque, and has a discrete region extending substantially the length of the polishing sheet that is at least semi-transparent.

Abstract: A polishing article for chemical mechanical polishing. The polishing article includes a generally elongated polishing sheet with a polishing surface. The polishing article is formed from a material that is substantially opaque, and has a discrete region extending substantially the length of the polishing sheet that is at least semi-transparent.

Abstract: Method and apparatus are provided for polishing substrates comprising conductive and low k dielectric materials with reduced or minimum substrate surface damage and delamination. In one aspect, a method is provided for processing a substrate including positioning a substrate having a conductive material formed thereon in a polishing apparatus having one or more rotational carrier heads and one or more rotatable platens, wherein the carrier head comprises a retaining ring and a membrane for securing a substrate and the platen has a polishing article disposed thereon, contacting the substrate surface and the polishing article to each other at a retaining ring contact pressure of about 0.4 psi or greater than a membrane pressure, and polishing the substrate to remove conductive material.

Abstract: Method and apparatus are provided for polishing conductive materials with low dishing of features and reduced or minimal remaining residues. In one aspect, a method is provided for processing a substrate by polishing the substrate to remove bulk conductive material and polishing the substrate by a ratio of carrier head rotational speed to platen rotational speed of between about 2:1 and about 3:1 to remove residual conductive material. In another aspect, a method is provided for processing a substrate including polishing the substrate at a first relative linear velocity between about 600 mm/second and about 1900 mm/second at the center of the substrate, and polishing the substrate at a second relative linear velocity between about 100 mm/second and about 550 mm/second at the center of the substrate.

Abstract: A carrier head for chemical mechanical polishing, includes a base, a support structure attached to the base having a surface for contacting a substrate, and a retaining structure attached to the base to prevent the substrate from moving along the surface. The retaining structure and the surface define a cavity for receiving the substrate. The retaining structure includes an upper portion in contact with the base, a lower portion, and a vibration damper separating the upper portion and the lower portion. The vibration damper, the vibration damper includes a material that does not rebound to its original shape when subjected to a deformation.

Abstract: A method and apparatus for using fixed abrasive polishing pads that contain posts for chemical mechanical polishing (CMP). The posts have different shapes, different sizes, different heights, different materials, different distribution of abrasive particles and different process chemicals. This invention also includes preconditioning fixed abrasive articles comprising a plurality of posts so that the posts have equal heights above the backing to achieve a uniform texture. This invention relates to improvements with respect to in situ rate measurement (ISRM) devices. The invention resides in providing a mechanical means, such as a notch, to determine when approaching the end of the abrasive web roll. The invention resides in coding the web throughout its length to enable determining the location of different portions of the web. This invention resides in providing perforations in the sides or end of the web for improved handling.

Abstract: A chemical mechanical polishing apparatus has a polishing surface, a carrier head to press a substrate against the polishing surface with a controllable pressure, a motor to generate relative motion between the polishing surface and the carrier head at a velocity, and a controller. The controller is configured to vary at least one of the pressure and velocity in response to a signal that depends on the friction between the substrate and the polishing surface to maintain a constant torque, frictional force, or coefficient of friction.

Abstract: A method and composition for planarizing a substrate surface having a barrier layer disposed thereon. In one aspect, the invention provides for planarizing a substrate surface having a barrier layer and a copper containing material disposed thereon including chemical mechanical polishing the substrate to selectively remove excess copper containing material, chemical mechanical polishing the substrate to selectively remove residual copper containing material and a portion of the barrier layer, and chemical mechanical polishing the substrate to selectively remove residual barrier layer.

Abstract: A carrier head for chemical mechanical polishing, includes a base, a support structure attached to the base having a surface for contacting a substrate, and a retaining structure attached to the base to prevent the substrate from moving along the surface. The retaining structure and the surface define a cavity for receiving the substrate. The retaining structure includes an upper portion in contact with the base, a lower portion, and a vibration damper separating the upper portion and the lower portion. The vibration damper, the vibration damper includes a material that does not rebound to its original shape when subjected to a deformation.

Abstract: The present invention generally provides a system and apparatus for cleaning a polishing pad, such as a fixed abrasive pad, in a substrate processing system. In one embodiment, the system includes one or more nozzles which spray a fluid at pressures of about 30 psi to about 300 psi or greater, as measured at the nozzle, onto a polishing pad at acute angles to the surface of the polishing pad. The nozzles can spray downward and outward toward the perimeter of the pad to facilitate the debris removal therefrom. The system can include a pressure source to produce a sufficient fluid pressure substantially higher than the typical fluid pressure available from a facility installation.

Abstract: Generally, a method and apparatus for cleaning a backside of a web of polishing material. In one embodiment, the apparatus includes a platen having a support surface adapted to support the backside the web and a web cleaner disposed on the platen and adjacent the backside of the web. A method for cleaning a web of polishing material is also provided. In one embodiment, the method includes the steps of supporting a portion of the web of polishing media on a platen, advancing a portion of the web onto the platen, and cleaning the unrolled portion of the web.

Abstract: Deposited Cu is initially removed by CMP with fixed abrasive polishing pads stopping on the barrier layer, e.g., Ta or TaN. Buffing is then conducted selectively with respect to Cu: Ta or TaN and Cu: silicon oxide to remove the barrier layer and control dishing to no greater than 100 Å.

Abstract: A method and composition for planarizing a substrate. The composition includes one or more surfactants, including one or more anionic surfactants, Zweitter-ionic surfactants, dispersers, or combinations thereof, one or more chelating agents, one or more oxidizers, one or more corrosion inhibitors, and deionized water. The composition may further comprise one or more agents to adjust the pH and/or abrasive particles. The method comprises planarizing a substrate using a composition including one or more surfactants of anionic surfactants, Zweitter-ionic surfactants, or combinations thereof.

Abstract: A method, composition, and computer readable medium for planarizing a substrate. In one aspect, the composition includes one or more chelating agents and ions of at least one transition metal, one or more surfactants, one or more oxidizers, one or more corrosion inhibitors, and deionized water. The composition may further comprise one or more agents to adjust the pH and/or abrasive particles. The method comprises planarizing a substrate using a composition including one or more chelating agents and ions of at least one transition metal.

Abstract: Method and apparatus for improving the reproducibility of chucking forces of an electrostatic chuck used in plasma enhanced CVD processing of substrates provides for precoating of the electrostatic chuck with a dielectric layer, such as SiO2, after every chamber cleaning process. The uniform and tightly bonded dielectric layer deposited on the electrostatic chuck eliminates the need for a cover wafer over the chuck surface during the chamber cleaning and provides for more reliable gripping of wafers.

Abstract: A polishing article for chemical mechanical polishing. The polishing article includes a generally elongated polishing sheet with a polishing surface. The polishing article is formed from a material that is substantially opaque, and has a discrete region extending substantially the length of the polishing sheet that is at least semi-transparent.

Abstract: A chemical mechanical polishing apparatus has a polishing surface, a carrier head to press a substrate against the polishing surface with a controllable pressure, a motor to generate relative motion between the polishing surface and the carrier head at a velocity, and a controller. The controller is configured to vary at least one of the pressure and velocity in response to a signal that depends on the friction between the substrate and the polishing surface to maintain a constant torque, frictional force, or coefficient of friction.

Abstract: An apparatus is provided for depositing and polishing a material layer on a substrate. In one embodiment, an apparatus is provided which includes a basin, a cover, a permeable disc, an anode and a polishing head. The permeable disc is disposed in the basin between the cover and the basin's bottom. The cover has an aperture disposed therein that includes a plurality of pins. The pins extend radially into the aperture and are adapted to support the substrate. The anode is disposed in the basin between the disc and the bottom of the basin. The polishing head is adapted to retain the substrate during processing and includes a retaining ring. The retaining ring has a plurality of grooves disposed therein that mate with the pins when the polishing head is disposed in the aperture. When the substrate is biased via the pins, the potential between the substrate and the anode causes material to be deposited on the substrate's surface.

Abstract: Generally, a method and apparatus for retaining polishing material is provided. In one embodiment, the apparatus includes a platen having a top surface, a plurality of channels and one or more vacuum ports. The top surface is adapted to support the polishing material. The plurality of channels are formed in a polishing area of the top surface. The vacuum ports are disposed in the platen and at least one port is in communication with at least one of the channels. Upon application of a vacuum to the ports, the channels remove fluids under the polishing material while securing the polishing material to the top surface.

Abstract: A method of chemically polishing a metal layer on a substrate is provided. The metal layer is chemically polished using an electrochemical polishing (ECP) process. In the ECP process, the substrate is immersed in a chemical polishing solution including a surfactant. The surfactant in the polishing solution covers the surface of the substrate such that only topographic portions of the substrate surface are exposed to the chemical polishing solution. Thereafter, an electrical potential applied to the substrate removes topographic portions of the substrate that are exposed to the polishing solution.